JP2020090809A - Construction method of impervious wall - Google Patents

Abstract

To provide a construction method of an impervious wall capable of constructing an impervious wall having sufficient strength, without any problem in mixing properties of bentonite and the ground.SOLUTION: The construction method of an impervious wall supplies bentonite liquid BW having exchangeable cations to the ground G, supply alkali earth type metallic bentonite powder CP and ion exchange agent powder IP to the ground G, and agitate the ground G as appropriate.SELECTED DRAWING: Figure 1

Description

The present invention relates to a method of constructing an impermeable wall.

As a method of constructing the impermeable wall, for example, there is one disclosed in Patent Document 1. The method disclosed in the document is to supply muddy water such as Ca-type bentonite into the ground and mix it, and further to supply into the ground a liquid of an ion exchange agent for modifying Ca-type bentonite or the like into Na-type bentonite or the like. To mix. According to the document, when a powder of bentonite is added, there is a problem in homogeneous mixing property, and Ca-type bentonite and the like and an ion exchange agent are supplied in liquid form.

However, according to this method, a large amount of water is injected into the ground, and it seems that the impermeable wall becomes soft.

Japanese Patent No. 6163173

The main problem to be solved by the present invention is to provide a method of constructing an impermeable wall that is capable of constructing an impermeable wall having no problem with the compatibility of bentonite and ground and having sufficient strength. .

Means for solving the above problems are as follows.
(Means according to claim 1)
It is a method of constructing an impermeable wall that supplies bentonite to the ground and agitates it.
Supplying bentonite liquid having exchangeable cations to the ground,
Next, a powder of alkaline earth metal type bentonite and a powder of ion exchange agent are supplied to the ground.
A method of constructing an impermeable wall, which is characterized in that

(Means according to claim 2)
The bentonite liquid having the exchangeable cation is an alkaline earth metal bentonite liquid,
The concentration of the liquid of the alkaline earth metal type bentonite is 5 to 60 W/V%,
The method for constructing a water impermeable wall according to claim 1.

(Means according to claim 3)
The supply amount of the liquid of the alkaline earth metal type bentonite per 1 m ^{3 of the} ground is 50 to 200 L,
The amount of the powder of the alkaline earth metal type bentonite supplied is such that the total amount of the bentonite supplied per 1 m ^{3 of the} ground is 50 to 300 kg,
The method for constructing the impermeable wall according to claim 2.

(Means according to claim 4)
The ion exchange agent is sodium carbonate,
The amount of the ion exchange agent supplied is 0.01 to 0.2 kg per 1 kg of the alkaline earth metal type bentonite.
The method for constructing the impermeable wall according to claim 2 or 3.

According to the present invention, there is provided a method of constructing an impermeable wall which has no problem in mixing the bentonite and the ground and is capable of constructing an impermeable wall having sufficient strength.

It is explanatory drawing which shows the procedure of the construction method of an impermeable wall.

Next, a mode for carrying out the present invention will be described. The present embodiment is an example of the present invention. The scope of the present invention is not limited to the scope of this embodiment.

As shown in FIG. 1, in the method of constructing the impermeable wall of the present embodiment, first, a bentonite liquid BW having an exchangeable cation which is an interlayer cation is supplied (injected) to the ground G (pretreatment 100). . Next, the alkaline earth metal type bentonite powder CP having the alkaline earth metal ion which is a polyvalent cation as the interlayer cation and the ion exchange agent powder IP are supplied (supplied) to the ground G (after). Line processing 200).

Then, the ground G is stirred at an appropriate stage to mix bentonite and the like with the ground G. This mixing can be performed in the process (100, 200) of supplying the liquid BW or the powder CP, IP, or before or after this process (100, 200). Specifically, for example, it can be performed in the middle (process) of the preceding process 100 and the following process 200 only after the preceding process 100 and the following process 200, or only after the following process 200.

In the present embodiment, bentonite means clay containing montmorillonite as a main component. The interlayer cation means an ion existing between the layers of montmorillonite. Examples of interlayer cations include monovalent cations such as sodium ions and lithium ions, and divalent or trivalent or more cations such as calcium ions and magnesium ions. Below, regarding various bentonites, the case where a large amount of alkali metal ions such as sodium ions are contained as interlayer cations is referred to as “Na-type bentonite” or “alkali metal-type bentonite”. Moreover, the case where a large amount of alkaline earth metal ions such as calcium ions and magnesium ions are contained as interlayer cations is referred to as “Ca type bentonite” or “alkaline earth metal type bentonite”.

Na-type bentonite is excellent in swelling property and thickening property. Therefore, it is suitable for constructing impermeable walls. However, in the case of converting Na-type bentonite into muddy water (liquid), it is difficult to increase the concentration. On the other hand, Ca-type bentonite is inferior in swelling property and thickening property. Therefore, it is not suitable for constructing impermeable walls. However, when muddy water (liquid) is used, there is an advantage that it is easy to increase the concentration.

On the other hand, the interlayer cation of montmorillonite is an exchangeable cation because it is easy to exchange ions with other cations. Therefore, one of the features of the present embodiment is to utilize both characteristics of Na-type bentonite and Ca-type bentonite by using an ion exchange agent. Therefore, in the present embodiment, the ion-exchange agent means a chemical agent capable of reforming (ion-exchange) Ca-type bentonite into Na-type bentonite.

The Na-type bentonite obtained by ion-exchanging (reforming) Ca-type bentonite is also called modified Na-type bentonite or activated Na-type bentonite. The reaction formula in the case of ion exchange using sodium carbonate is as follows.
Be-Ca + Na ₂ CO ₃ → Be-Na + CaCO ₃

In the pretreatment 100, bentonite liquid BW having exchangeable cations can be widely used. However, as the bentonite liquid BW having exchangeable cations, it is preferable to use a Ca-type bentonite liquid. As described above, the Ca-type bentonite can have a high concentration and can reduce the amount of water injected into the ground G. Reducing water injection reduces the amount of sludge and improves the strength of the impermeable walls. Furthermore, if the concentration is high, the dispersibility of bentonite is improved.

When a Ca-type bentonite liquid is used, the concentration of the liquid is preferably 1 to 80 W/V%, more preferably 3 to 70 W/V%, and particularly preferably 5 to 60 W/V%. When the concentration is less than 1 W/V%, the wall-forming property of the bentonite liquid BW (for example, the performance of preventing the ground G from collapsing) may be insufficient. On the other hand, if the concentration is higher than 80 W/V%, it may be difficult to produce liquid.

The concentration of the liquid of Ca-type bentonite means the ratio (%) of the mass (kg) of bentonite per 1 m ³ of the slurry (muddy water) working water (outer percentage). Therefore, for example, 5 to 60 W/V% means 50 to 600 kg/m ³ .

In the subsequent process 200, Ca-type bentonite powder CP is used. Ca-type bentonite is inferior in swelling property and thickening property, but even if it is a powder, it can be easily mixed with the ground G. This is because the Ca-type bentonite powder has a smaller water-swelling swelling property than the Na-type bentonite powder, and therefore even if it is added to water and mixed, it does not become a powdered powder (mamako) and is uniformly dispersed. This is because Further, by supplying Ca-type bentonite in the subsequent process 200, the supply of bentonite in the preceding process 100 can be reduced. Further, if the powder is used, the amount of water supplied (injected) to the ground G is reduced, so that the strength of the obtained impermeable wall is improved. That is, the powder is advantageous in that the water-impervious wall can be hardened and the amount of bentonite can be supplied to the ground G while the amount of discharged mud can be reduced.

However, from the viewpoint of reducing the amount of water supplied to the ground G, it is preferable to use a high concentration Ca-type bentonite liquid in the pretreatment 100, and the Ca-bentonite in the pretreatment 100 and the subsequent treatment 200 has the following proportions. Is more preferably used.

First, in the preliminary treatment 100, the injection amount of the liquid BW (concentration 5 to 60 W/V%) of Ca-type bentonite per ground G (1 m ³ ) varies depending on the soil quality of the target ground, but preferably 10 to 400 L, It is more preferably 20 to 300 L, and particularly preferably 50 to 200 L.

On the other hand, in the subsequent process 200, the amount of Ca-type bentonite powder CP added is preferably the total amount of bentonite supplied per ground G (1 m ³ ) (in the present embodiment, the liquid BW of bentonite and the bentonite). The total amount of the powder CP) is 50 to 300 kg.

Note that the Na-type bentonite muddy water may reach the pumping limit at a concentration of around 10%, but the Ca-type bentonite muddy water can be fed even at a high concentration of 50 to 60%. Therefore, if a high concentration of Ca bentonite muddy water is used, a large amount of bentonite can be supplied to the ground G even with the same injection amount, and the supply amount of bentonite powder thereafter can be reduced accordingly. For example, as will be apparent from the examples described below, when the construction is performed such that the total amount of bentonite in the ground G is 100 kg, the supply amount of Ca-type bentonite powder after injecting 100 L of muddy water (5%) is 95 kg In contrast to Table 1), the supply amount of Ca-type bentonite powder after pouring 100 L of muddy water of concentration (50%) is 58 kg (see Table 2), which can be reduced by about 40%.

In the present embodiment, as the ion-exchange agent, a general agent that can modify (ion-exchange) Ca-type bentonite into Na-type bentonite can be used. Specifically, for example, an ion exchange agent composed of sodium carbonate, sodium hydrogen carbonate, sodium percarbonate, sodium hydroxide, sodium citrate, sodium silicate, or the like, a phosphoric acid-based ion exchange agent, or a silica-based ion exchange agent. One kind or two or more kinds can be selected from the above and used. However, it is preferable to use an ion exchange agent that ion-exchanges an alkali metal ion such as sodium ion with an alkaline earth metal ion such as calcium ion and insolubilizes or chelates the precipitated alkaline earth metal ion to cause precipitation. As such an ion exchange agent, for example, an ion exchange agent such as a sulfuric acid salt, a phosphoric acid salt, a silicic acid salt, an ethylenediamine salt, a carboxylic acid salt is preferably used, and sodium carbonate is used. Is more preferable.

The amount of the ion exchange agent added is preferably 0.01 to 0.2 kg, more preferably 0.02 to 0.15 kg, and particularly preferably 0.03 to 0.1 kg, relative to Ca-type bentonite (1 kg). is there. If the amount added is less than 0.01 kg, the Ca-type bentonite may not be sufficiently modified. On the other hand, if the amount added exceeds 0.2 kg, the ion exchange agent may be in excess.

The ion-exchange agent powder IP may be supplied to the ground G separately from the Ca-type bentonite powder CP, or may be mixed and then supplied to the ground G.

(Other)
The construction method of the present embodiment uses, for example, a "chain cutter type excavator equipped with a movable base machine and a cutter for excavating the ground" as disclosed in Japanese Patent Laid-Open No. 2005-16295. (Equal thickness type) or when constructing an impermeable wall using a "drilling device equipped with a single-axis or multi-axis drilling shaft" as disclosed in JP 2006-291703 A ( It can be applied to the case of constructing an impermeable wall using a backhoe equipped with a column) and a bucket.

Next, examples of the present invention will be described.
(Test 1)
In this test, first, bentonite muddy water was added to sand (A) and mixed (first mixing). As the bentonite muddy water, a low concentration (5%) Ca-type bentonite liquid (muddy water) or an activated Ca-type bentonite liquid (muddy water) was used. Next, Ca-type bentonite powder and soda ash (sodium carbonate) powder were added to the sand after the first mixing and mixed (second mixing). Table 1 shows the table flow values after the first mixing and after the second mixing, and the water permeability. Regarding the water permeability, the following standards exist.
Environmental site conditions: 1×10 ^-8 m/sec or less Civil engineering site conditions: 1×10 ^-6 m/sec or less

The table flow value is an index of fluidity, which corresponds to the time of excavation during the first mixing, and corresponds to the time of construction during the second mixing. For example, if the table flow value at the time of construction is 130 or less, almost no fluidization occurs, and if a specified amount of bentonite is added, the hardness will be no problem with water impermeability for environmental sites. ..

(Test 2)
In this test, first, bentonite muddy water and soda ash were added to the sand (A) and mixed (first mixing). As the bentonite muddy water, a high-concentration (50%) Ca-type bentonite liquid (muddy water) was used. Next, nothing was added to the sand after the first mixing, or the powder of Ca-type bentonite and the powder of soda ash were added and mixed (second mixing). Table 2 shows the table flow values after the first mixing and after the second mixing, and the water permeability.

It can be seen from Table 2 that it is preferable to add not only soda ash but also Ca-type bentonite powder.

(Test 3)
In the present test, first, bentonite muddy water, Ca-type bentonite powder, and soda ash powder were added to sand (A) and mixed (first mixing). As the bentonite muddy water, a Ca-type bentonite liquid (muddy water) was used. Next, the powder of Ca type bentonite and the powder of soda ash were added to the sand after the first mixing and mixed (second mixing). Table 3 shows the table flow values after the first mixing and after the second mixing, and the water permeability. Furthermore, the same test was performed using Ca-type bentonite (B) from different production areas (Test Example 15 and Test Example 16).

From Table 3, it can be seen that the fluidity can be adjusted to an appropriate level by adding the powder of Ca-type bentonite together with the muddy water during the first mixing.

INDUSTRIAL APPLICABILITY The present invention can be used as a method of constructing an impermeable wall.

100 Pretreatment 200 Subsequent treatment BW Bentonite muddy water CP Ca-type bentonite powder IP Ion-exchanger powder G Ground

Claims (4)

It is a method of constructing an impermeable wall that supplies bentonite to the ground and agitates it.
Supplying bentonite liquid having exchangeable cations to the ground,
Next, a powder of alkaline earth metal type bentonite and a powder of ion exchange agent are supplied to the ground.
A method of constructing an impermeable wall, which is characterized in that The bentonite liquid having the exchangeable cation is an alkaline earth metal bentonite liquid,
The concentration of the liquid of the alkaline earth metal type bentonite is 5 to 60 W/V%,
The method for constructing a water impermeable wall according to claim 1. The supply amount of the liquid of the alkaline earth metal type bentonite per 1 m ^{3 of the} ground is 50 to 200 L,
The amount of the powder of the alkaline earth metal type bentonite supplied is such that the total amount of the bentonite supplied per 1 m ^{3 of the} ground is 50 to 300 kg,
The method for constructing the impermeable wall according to claim 2. The ion exchange agent is sodium carbonate,
The amount of the ion exchange agent supplied is 0.01 to 0.2 kg per 1 kg of the alkaline earth metal bentonite.
The method for constructing the impermeable wall according to claim 2 or 3.

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